Facilitating Interdisciplinary Research through IGERT: Integrative Graduate Research and Traineeship Program

1. Facilitating Interdisciplinary Research through IGERT: Integrative Graduate Research and Traineeship Program  Ram M. K. Ramasubramanian, PhD Program Director mramasub@nsf.gov

2. Educational Paradigms The challenges of educating 21st Century scientists, mathematicians, and engineers mandate a new paradigm in science and engineering graduate education.

3. Today�s Research Trends Research interdisciplinary Work across disciplines Research collaborative Teamwork Research varied settings Preparation for varied careers Research global International activities and experiences

4. Skills set - technical, Professional & Personal Discovery and Innovation. Skills include fundamental research, technical training with broad intellectual content, problem-formulation and problem-solving. Intellectual Integration. Knowledge-integration skills include inter- and multidisciplinary research, systems research and real-world problems, cross intellectual boundaries, and the skills necessary to work in teams and to teach others. Knowledge Transfer. Skills encompass communication, education, and publication, together with linkages to industry and national laboratories.

5. Skills set-technical, Professional & Personal 4. Tools. Skills address computational science and scientific modeling, together with language skills and knowledge of international cultures. 5. Professional Responsibility. Openness and intellectual integrity, and the values and goals appropriate for knowledge in the service of society.

6. IGERT Program Goals The Integrative Graduate Education and Research Traineeship (IGERT) program has been developed to meet the challenges of educating U.S. Ph.D. scientists and engineers who will pursue careers in research and education, with the interdisciplinary backgrounds, deep knowledge in chosen disciplines, and technical, professional, and personal skills to become, in their own careers, leaders and creative agents for change.

7. IGERT Program Goals The program is intended to catalyze a cultural change in graduate education, for students, faculty, and institutions, by establishing innovative new models for graduate education and training in a fertile environment for collaborative research that transcends traditional disciplinary boundaries.

8. IGERT Program Goals It is also intended to facilitate diversity in student participation and preparation, and to contribute to a world-class, broadly inclusive, and globally engaged science and engineering workforce.

9. Integrative Graduate Education and Research Traineeship (IGERT) Dual focus on a transformative interdisciplinary research theme and an aligned innovative educational plan for US PhD students Awards to institutions ($3-3.2M/5 years); senior PIs Recent competitions have > 400 pre-proposals, ~20 awards (5%) Since 1997: 240 awards 110 different lead institutions 43 states, DC, and Puerto Rico ~25 trainees/award, typically supported 2 years/each ~5,200 PhD students have been supported Intended to catalyze sustainable institutional change in graduate education for the training of future scientific research workforce

10. Support Level 5-year awards Up to $600K per year Up to $200K additional in the first year for equipment, special materials, or methodologies, part of the total $600K Additional International Training Component $50K per year for years 2-5 Indirect limitation: 8% of total direct costs excluding equipment and COE Graduate student stipend $30,000, Cost of education expenses $10,500 20 new awards anticipated for the 2010 competition.

12. IGERT Program Characteristics Interdisciplinary theme plus disciplinary depth Emerging research area Innovative models for graduate education Broaden participation Catalyze a cultural change in graduate education For graduate students For faculty For institutions

13. The Value of Interdisciplinary Research To faculty: Funding NIH recognizes multiple PIs NSF has collaborative submission process Universities considering tenure and promotion policies To academia: Research institutes To industry: Practical problem-solving

14. Some Features of IGERT Encourages experiments that may result in changes of existing models for Graduate Education Emphasizes a type of Counter-Cultural Research and Education Experiment Provides a substantial increase in resources for enhanced impact Provides a framework wherein institutions, through PIs, can propose programs with enough flexibility to accommodate students� desire to design an education plan to match his/her career goals Provides a means for program performance assessment

15. How do you build an IGERT?

17. Some IGERT Interdisciplinary Themes Smart sensors and integrated devices Biosphere-atmosphere research Molecularly designed materials Assistive technology Sequential decision-making Urban ecology Astrobiology Alternate Energy Nanotechnology

18. IGERT Proposal Characteristics Senior PI Co-PI from other departments and colleges Faculty Participants, up to 20, from various disciplines relevant to the research theme Strong Institutional Support Not necessarily $ Institutionalization plan and support Facilitating curricular changes Strong support for broadening participation Strong letters of support from partners

19. IGERT Proposal Characteristics Research themes and thrust areas very clearly and concisely articulated Identification of academic preparation needed for PhD students to be successful Strong and well thought out educational plan indicating curricular development Description of new courses and development plans Strong Mentoring plan Attention to detail on degree requirements across disciplinary boundaries

20. IGERT Examples

21. Theme: Environmental Change and Implications for Humanity Dartmouth: Polar Environmental Change George Washington University: Dynamics of Behavioral Shifts in Human Evolution: Brains, Bodies, and Ecology UCSD: Marine Biodiversity: Understanding Threats and Providing Solutions

22. Theme: Clean Energy and Engineering Processes Texas Tech University: Wind Science and Engineering

23. Nanoscale Science in IGERT 24 active awards including 4 renewals directly focused on Nanoscale Science Nanoscale Science in Biology Devices and machines Electronics Fabrication Laminates Materials; Biomaterials Medical Particles Pharmaceutical Photonics Probes

24. Universities with Nanoscale Science related IGERTs Cornell (3) Drexel University Johns Hopkins University Northeastern University Ohio State University Rutgers University (3) Tuskegee University UC-Berkeley UC-Los Angeles (2) University of Massachusetts Amherst University of New Mexico (2) University of South Dakota University of Texas Austin University of Utah (2) University of Washington Vanderbilt University William Marsh Rice University

25. Educational Features of IGERT Projects New curricula Interdisciplinary courses, laboratories, seminars, often team-taught Student-taught interdisciplinary courses Distance learning, videoconferencing New integrative experiences �boot camps,� workshops, retreats Team projects and teamwork exercises Student-lead and -organized meetings Laboratory rotations; co-advising Internships Industry, national laboratory, research institute International

26. Further Educational Features of IGERT Projects Communications training K-12, general public, government Ethics and responsible conduct of research Tailored to IGERT topic IP, patents, business plans Professional development Activities for broadening participation

27. Examples of Nanoscale Science Courses Fundamental Physics and Chemistry of Nanomaterials; Interfacial Phenomena in Nanostructured Materials (Johns Hopkins U.) Nanosystems Design for Biology and Medicine (Northeastern U.) Nanotechnology: From Lab to Product (U. Mass Amherst) Nanotechnology-Based Drug Delivery (Rutgers U.) Frontiers in Nanotechnology (U. Washington) Quantum Engineering of Nanostructures (U. Texas at Austin) Nanoscale Materials; Molecular Modeling of Polymers and Nanocomposites (Tuskegee U.) Imaging Nanostructures and Nanoparticles; Finite Element Analysis for Nanostructures (modules, Cornell University) Biomedical Applications of Colloidal Nanocrystals (U. of New Mexico)

28. Examples of Credentials Certificates, minors, concentrations Certificate program in Nanotechnology (Drexel-U. Pennsylvania) Certificate program in Biomedical Science and Engineering with Concentration in Nanotechnology (U. New Mexico) Designated Emphasis in Nanoscale Science and Engineering (UC Berkeley) Dual degree programs Home department and Nanotechnology (U. Washington) Doctoral programs Ph.D. in Nanoscience and Microsystems (U. New Mexico)

29. IGERT Partnerships Within universities: between faculty, departments, schools, colleges Between universities: Leverage resources Broaden participation Outside academia National laboratories and research institutes Industry International universities and institutions At the funding agency level IGERT is a cross-cutting program

30. IGERT Evaluation StudyInitial Impacts Both IGERT and non-IGERT samples of first three cohorts (1998-2000) Graduate Students Faculty Administrators Benefits and Challenges for All

31. Current Evaluation Next three cohorts of IGERT Trainee post-graduation follow-up Follow up study nearing completion. Report will be published shortly.

32. www.igert.org

33. Find Out More About IGERT http://www.IGERT.org Searchable site maintained by grantee http://www.nsf.gov/funding/pgm_summ.jsp?pims_id=12759&org=DGE&from=home IGERT home page at NSF Program solicitation Video presentation http://www.nsf.gov/pubs/2006/nsf0617/index.jsp Impacts of IGERT evaluation http://www.nsf.gov/pubs/2008/nsf0840/index.jsp IGERT 2006-2007 Annual Report

34. Program Goals Graduate Students Communication, Leadership, Team building K-12 Education Enhanced Teaching and Learning Higher Education Transform Graduate Programs

35. Annual Budget $55+ Million GK-12 has made 276 awards at 144 institutions. Funded 5,623 Graduate Fellows. Provided resources for 9,473 K-12 Teachers, working in 4,732 different schools. 687,594 K-12 Students have been impacted by GK-12.

37. Funding Amount

38. Types of Institutions

39. NSF Supported STEM Disciplines

40. Eligibility Lead academic institution must be in the United States or its territories and grant masters or doctoral degrees in STEM disciplines supported by the NSF Principal Investigator(PI) must be a STEM discipline faculty member actively conducting STEM research at lead institution One proposal may be submitted per institution Institutions having an active or past GK-12 project are eligible, but must coordinate evaluation efforts; Must be a new proposal, clarify what are the differences between the new and existing or past ones